Your search keyword '"Briant, L J B"' showing total 3 results

1. δ-cells and β-cells are electrically coupled and regulate α-cell activity via somatostatin

Author

Briant, L. J. B., Reinbothe, T. M., Spiliotis, I., Miranda, C., Rodriguez, B., and Rorsman, P.

Subjects

Male, endocrine system, Somatostatin-Secreting Cells, Cell Communication, Mice, computer modelling, Insulin-Secreting Cells, Animals, Insulin, Computer Simulation, alpha cell, optogenetics, Cells, Cultured, delta cell, Gap Junctions, electrophysiology, Glucagon, beta cell, Glucose, Glucagon-Secreting Cells, Islet cell, Calcium, Female, Endocrine, Nutrition and Metabolism, Somatostatin, Research Paper, Perspectives

Abstract

Key points We used a mouse expressing a light‐sensitive ion channel in β‐cells to understand how α‐cell activity is regulated by β‐cells.Light activation of β‐cells triggered a suppression of α‐cell activity via gap junction‐dependent activation of δ‐cells.Mathematical modelling of human islets suggests that 23% of the inhibitory effect of glucose on glucagon secretion is mediated by β‐cells via gap junction‐dependent activation of δ‐cells/somatostatin secretion. Abstract Glucagon, the body's principal hyperglycaemic hormone, is released from α‐cells of the pancreatic islet. Secretion of this hormone is dysregulated in type 2 diabetes mellitus but the mechanisms controlling secretion are not well understood. Regulation of glucagon secretion by factors secreted by neighbouring β‐ and δ‐cells (paracrine regulation) have been proposed to be important. In this study, we explored the importance of paracrine regulation by using an optogenetic strategy. Specific light‐induced activation of β‐cells in mouse islets expressing the light‐gated channelrhodopsin‐2 resulted in stimulation of electrical activity in δ‐cells but suppression of α‐cell activity. Activation of the δ‐cells was rapid and sensitive to the gap junction inhibitor carbenoxolone, whereas the effect on electrical activity in α‐cells was blocked by CYN 154806, an antagonist of the somatostatin‐2 receptor. These observations indicate that optogenetic activation of the β‐cells propagates to the δ‐cells via gap junctions, and the consequential stimulation of somatostatin secretion inhibits α‐cell electrical activity by a paracrine mechanism. To explore whether this pathway is important for regulating α‐cell activity and glucagon secretion in human islets, we constructed computational models of human islets. These models had detailed architectures based on human islets and consisted of a collection of >500 α‐, β‐ and δ‐cells. Simulations of these models revealed that this gap junctional/paracrine mechanism accounts for up to 23% of the suppression of glucagon secretion by high glucose., Key points We used a mouse expressing a light‐sensitive ion channel in β‐cells to understand how α‐cell activity is regulated by β‐cells.Light activation of β‐cells triggered a suppression of α‐cell activity via gap junction‐dependent activation of δ‐cells.Mathematical modelling of human islets suggests that 23% of the inhibitory effect of glucose on glucagon secretion is mediated by β‐cells via gap junction‐dependent activation of δ‐cells/somatostatin secretion.

Published

2017

2. Quantifying sympathetic neuro-haemodynamic transduction at rest in humans:Insights into sex, ageing and blood pressure control

Author

Briant, L J B, Burchell, A E, Ratcliffe, L E K, Charkoudian, N, Nightingale, A K, Paton, J F R, Joyner, Michael J, and Hart, E C

Subjects

Bristol Heart Institute, CRICBristol

Abstract

Sex and age differences in the sympathetic control of resting blood pressure (BP) may be due to differences in the transduction of sympathetic nerve activity (SNA) into vascular tone. Current methods for dynamically quantifying transduction focus on the relationship between SNA and vasoconstriction during a pressor stimulus, which increases BP and may be contra-indicated in patients. We describe a simple analytical method for quantifying transduction under resting conditions. We performed linear regression analysis of binned muscle SNA burst areas against diastolic BP (DBP). We assessed whether the slope of this relationship reflects the transduction of SNA into DBP. To evaluate this, we investigated whether this measure captures differences in transduction in different populations. Specifically, we (1) quantified transduction in young men (YM), young women (YW), older men (OM) and postmenopausal women (PMW); and (2) measured changes in transduction during β-blockade using propranolol in YW, YM and PMW. YM had a greater transduction vs. OM (0.10 ± 0.01mmHg/ %·s, n = 23vs. 0.06 ± 0.01mmHg/ %·s, n = 18; P = 0.003). Transduction was lowest in YW (0.02 ± 0.01 mmHg/%·s, n = 23) and increased during β-blockade (0.11 ± 0.01 mmHg/%·s; P < 0.001). Transduction in PMW (0.07 ± 0.01 mmHg/%·s, n = 23) was greater compared to YW (P = 0.001), and was not altered during β-blockade (0.06 ± 0.01 mmHg/%·s; P = 0.98). Importantly, transduction increased in women with age, but decreased in men. Transduction in women intersected that in men at 55 ± 1.5 years. This measure of transduction captures age- and sex-differences in the sympathetic regulation of DBP and may be valuable in quantifying transduction in disease. In particular, this measure may help target treatment strategies in specific hypertensive sub-populations.

Published

2016

3. δ-cells and β-cells are electrically coupled and regulate α-cell activity via somatostatin

Author

Briant, L. J. B., Reinbothe, T. M., Spiliotis, I., Miranda, C., Rodriguez, B., and Rorsman, P.